Fine-Grained Complexity via Quantum Natural Proofs

Yanlin Chen; Yilei Chen; Rajendra Kumar; Subhasree Patro; Florian Speelman

Fine-Grained Complexity via Quantum Natural Proofs

Yanlin Chen, Yilei Chen, Rajendra Kumar, Subhasree Patro, Florian Speelman

Coding Theory and Cryptology

Research output: Working paper › Preprint › Professional

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Abstract

Buhrman, Patro, and Speelman presented a framework of conjectures that together form a quantum analogue of the strong exponential-time hypothesis and its variants. They called it the QSETH framework. In this paper, using a notion of quantum natural proofs (built from natural proofs introduced by Razborov and Rudich), we show how part of the QSETH conjecture that requires properties to be `compression oblivious' can in many cases be replaced by assuming the existence of quantum-secure pseudorandom functions, a standard hardness assumption. Combined with techniques from Fourier analysis of Boolean functions, we show that properties such as PARITY and MAJORITY are compression oblivious for certain circuit class $\Lambda$ if subexponentially secure quantum pseudorandom functions exist in $\Lambda$, answering an open question in [Buhrman-Patro-Speelman 2021].

Original language	English
Publisher	arXiv.org
Number of pages	29
Volume	2504.10363
Publication status	Published - 14 Apr 2025

Keywords

quant-ph
cs.CC

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2504.10363v1Final published version, 390 KB

https://arxiv.org/abs/2504.10363

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title = "Fine-Grained Complexity via Quantum Natural Proofs",

abstract = "Buhrman, Patro, and Speelman presented a framework of conjectures that together form a quantum analogue of the strong exponential-time hypothesis and its variants. They called it the QSETH framework. In this paper, using a notion of quantum natural proofs (built from natural proofs introduced by Razborov and Rudich), we show how part of the QSETH conjecture that requires properties to be `compression oblivious' can in many cases be replaced by assuming the existence of quantum-secure pseudorandom functions, a standard hardness assumption. Combined with techniques from Fourier analysis of Boolean functions, we show that properties such as PARITY and MAJORITY are compression oblivious for certain circuit class $\Lambda$ if subexponentially secure quantum pseudorandom functions exist in $\Lambda$, answering an open question in [Buhrman-Patro-Speelman 2021]. ",

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AU - Chen, Yanlin

AU - Chen, Yilei

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AU - Patro, Subhasree

AU - Speelman, Florian

PY - 2025/4/14

Y1 - 2025/4/14

N2 - Buhrman, Patro, and Speelman presented a framework of conjectures that together form a quantum analogue of the strong exponential-time hypothesis and its variants. They called it the QSETH framework. In this paper, using a notion of quantum natural proofs (built from natural proofs introduced by Razborov and Rudich), we show how part of the QSETH conjecture that requires properties to be `compression oblivious' can in many cases be replaced by assuming the existence of quantum-secure pseudorandom functions, a standard hardness assumption. Combined with techniques from Fourier analysis of Boolean functions, we show that properties such as PARITY and MAJORITY are compression oblivious for certain circuit class $\Lambda$ if subexponentially secure quantum pseudorandom functions exist in $\Lambda$, answering an open question in [Buhrman-Patro-Speelman 2021].

AB - Buhrman, Patro, and Speelman presented a framework of conjectures that together form a quantum analogue of the strong exponential-time hypothesis and its variants. They called it the QSETH framework. In this paper, using a notion of quantum natural proofs (built from natural proofs introduced by Razborov and Rudich), we show how part of the QSETH conjecture that requires properties to be `compression oblivious' can in many cases be replaced by assuming the existence of quantum-secure pseudorandom functions, a standard hardness assumption. Combined with techniques from Fourier analysis of Boolean functions, we show that properties such as PARITY and MAJORITY are compression oblivious for certain circuit class $\Lambda$ if subexponentially secure quantum pseudorandom functions exist in $\Lambda$, answering an open question in [Buhrman-Patro-Speelman 2021].

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KW - cs.CC

M3 - Preprint

VL - 2504.10363

BT - Fine-Grained Complexity via Quantum Natural Proofs

PB - arXiv.org

ER -

Fine-Grained Complexity via Quantum Natural Proofs

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